尿酸钠结晶诱导痛风性关节炎动物模型研究进展

痛风性关节炎是由于机体嘌呤代谢紊乱,导致血内尿酸增高而引起尿酸盐在组织沉积的疾病,本文简要介绍大鼠尿酸钠结晶急性足跖肿胀模型、大鼠尿酸钠结晶急性痛风性踝关节炎模型、小鼠与大鼠尿酸钠结晶皮下气囊法急性痛风性滑膜炎模型和家兔尿酸钠结晶急性膝关节炎模型的制作方法进展。将有益于抗痛风性关节炎药物研究时的更多选择应用。     

减毒沙门氏菌作为DNA疫苗载体的研究进展

随着沙门氏菌基因组学的深入研究以及DNA重组技术的发展,使得对沙门氏菌进行精确的不可回复性的基因缺失减毒成为可能。减毒沙门氏菌可作为DNA疫苗载体,特异性地将其携带的质粒DNA靶向性的传递给巨噬细胞、树突细胞等抗原递呈细胞,从而有效激发相应的体液与细胞免疫应答。减毒沙门氏菌已作为疫苗载体在针对细菌、病毒、寄生虫等的DNA疫苗研究中得以广泛应用。     

乙肝核心抗原作为免疫载体蛋白的研究进展

乙肝核心抗原由于其天然的颗粒组装能力和特异性激发针对外源表位的体液免疫和细胞免疫作用的特性,成为载体蛋白研究的热点.本简要综述乙肝核心抗原的结构特点、免疫学特性、作为免疫载体蛋白的研究进展及其应用研究.     

Solution‐Processed Ternary Oxides as Carrier Transport/Injection Layers in Optoelectronics

With the remarkable progress in solution‐processed optoelectronics, high performance is required of the carrier transport/injection layer. Ternary oxides containing a variety of crystal structures, and adjustable composition that results in tunable optical and electrical properties, are one of the promising class of candidates to fulfill the requirements of carrier transport/injection layers for high‐performance and stable optoelectronic devices. Solution‐processed ternary oxides have seen considerable progress in recent decades, due to their advantages in the quest to design low‐cost, high‐performance, large‐scale, and stable optoelectronic devices. Herein, the recent advances of solution‐processed ternary oxides are reviewed. The first section consists of a brief introduction to the topic. In the following section, the fundamentals of the effect of tuning ternary oxide composition are summarized. Section three briefly reviews the synthesis approaches for preparing ternary oxides. Section four discusses the recent progress of solution‐processed ternary oxide as carrier transport/injection layer in optoelectronic devices (such as organic solar cells, perovskite solar cells, organic light emitting diodes, etc.). In this section, the impact of controlling ternary oxide composition on device performance and stability is highlighted. Finally, a brief summary and an outlook are given.     

Biosensors for the Determination of Ortho-acetyl-L-carnitine. Their Utilization as Detectors in a Sequential Injection Analysis System

Abstract

In order to determine ortho-acetyl-L-carnitine, two biosensors were proposed. The biosensors were designed using physical immobilization of L-amino acid oxidase (L-AAOD) and horseradish peroxidase (HRP). Electrode characteristics were obtained and compared for the two carbon paste (graphite powder and paraffin oil) biosensors. The linear concentration ranges for the proposed biosensors were in the ranges of fmol/L to nmol/L, magnitude order with low limits of detection. Due to their reliability, the biosensors were used as detectors in a sequential injection analysis system, and gave reliable results for on-line assay of ortho-acetyl-L-carnitine in synthesis process control with a frequency of 75 samples per hour.     

Electron Collection as a Limit to Polymer:PCBM Solar Cell Efficiency: Effect of Blend Microstructure on Carrier Mobility and Device Performance in PTB7:PCBM

The poor photovoltaic performance of state‐of‐the‐art blends of poly[4,8‐bis[(2‐ethylhexyl)oxy]benzo[1,2‐b:4,5‐b′]dithiophene‐2,6‐diyl][3‐fluoro‐2‐[(2‐ethylhexyl)carbonyl]thieno[3,4‐b]thiophenediyl] (PTB7) and [6,6]‐phenyl‐C61‐butyric acid (PCBM) at large active layer thicknesses is studied using space‐charge‐limited current mobility and photovoltaic device measurements. The poor performance is found to result from relatively low electron mobility. This is attributed to the low tendency of PTB7 to aggregate, which reduces the ability of the fullerene to form a connected network. Increasing the PCBM content 60–80 wt% increases electron mobility and accordingly improves performance for thicker devices, resulting in a fill factor (FF) close to 0.6 at 300 nm. The result confirms that by improving only the connectivity of the fullerene phase, efficient electron and hole collection is possible for 300 nm‐thick PTB7:PCBM devices. Furthermore, it is shown that solvent additive 1,8‐diiodooctane (DIO), used in the highest efficiency PTB7:PCBM devices, does not improve the thickness dependence and, accordingly, does not lead to an increase in either hole or electron mobility or in the carrier lifetime. A key challenge for researchers is therefore to develop new methods to ensure connectivity in the fullerene phase in blends without relying on either a large excess of fullerene or strong aggregation of the polymer.